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Letter
Rate Law Analysis of Water Oxidation and Hole Scavenging on a BiVO4 photoanode Yimeng Ma, Camilo Mesa, Ernest Pastor, Andreas Kafizas, Laia FrancasForcada, Florian Le Formal, Stephanie R. Pendlebury, and James R. Durrant ACS Energy Lett., Just Accepted Manuscript • DOI: 10.1021/acsenergylett.6b00263 • Publication Date (Web): 23 Aug 2016 Downloaded from http://pubs.acs.org on August 26, 2016
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Rate Law Analysis of Water Oxidation and Hole Scavenging on a BiVO4 photoanode Yimeng Ma,†, ‡ Camilo Mesa,† Ernest Pastor,† Andreas Kafizas,†, § Laia Francàs Forcada†, Florian Le Formal,†,∥ Stephanie R. Pendlebury † and James R. Durrant†,* †Department of Chemistry, Imperial College London, South Kensington Campus, London, SW7 2AZ, United Kingdom ‡Institute for Solar Fuels, Helmholtz-Zentrum Berlin für Materialien und Energie GmbH, HahnMeitner-Platz 1, Berlin, 14109, Germany §Christopher Ingold Laboratories, Department of Chemistry, University College London, Gordon Street, London, WC1H 0AJ, United Kingdom ∥Laboratory for Molecular Engineering of Optoelectronic Nanomaterials, Institute of Chemical Sciences and Engineering, École Polytechnique Fédérale de Lausanne (EPFL), Station 6, CH H4 565, Lausanne 1015, Switzerland Corresponding Author *James R. Durrant
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ABSTRACT Spectroelectrochemical studies employing pulsed LED irradiation are used to investigate the kinetics of water oxidation on undoped dense bismuth vanadate (BiVO4) photoanodes under conditions of photoelectrochemical water oxidation, and compared to those obtained for oxidation of a simple redox couple. These measurements are employed to determine the quasi steady-state densities of surface accumulated holes, ps, and correlate these with photocurrent density as a function of light intensity, allowing a rate law analysis of the water oxidation mechanism. The reaction order in surface hole density is found to be first order for ps < 1 nm-2, and third order for ps > 1 nm-2. The effective turn over frequency of each surface hole is estimated to be 14 s-1 at AM 1.5 condition. Using a single-electron redox couple, potassium ferrocyanide, as the hole scavenger, only the first order reaction is observed, with a higher rate constant than for water oxidation. These results are discussed in terms of catalysis by BiVO4 and implications for material design strategies for efficient water oxidation.
TOC GRAPHICS
reaction order
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BiVO4 photoanode water oxidation
2 1
K4[Fe(CN)6] oxidaton 0 0
1 2 3 4 surface hole density / nm-2
5
Solar-driven water oxidation on metal oxide semiconductors is central to many approaches for solar driven fuel synthesis.1-2 Bismuth vanadate, BiVO4, is a particularly promising photoanode material for water oxidation.1, 3 Employing various optimization strategies, including gradientdoping,4 surface modification,4-9 and the use of host-guest scaffolds,10 onset potentials for
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photoelectrochemical (PEC) water oxidation on BiVO4 as low as 0.2 V vs RHE and photocurrent densities at 1.23 VRHE as high as 4 mAcm-2 have been reported.7 Several studies on both BiVO4 and other oxide surfaces have identified the relatively slow (up to seconds) timescale of water oxidation on such oxides as a key limitation to photoanode performance.11-15 However, to date, studies of the kinetics and mechanism of water oxidation on BiVO4 surfaces have been very limited in the literature.1 Transient absorption studies have indicated a timescale for water oxidation on metal oxide surfaces, such as BiVO4 and hematite under short-pulsed laser excitation of 1 s,12-13, 16-18 whilst intensity-modulated photocurrent spectroscopic analyses have indicated timescales of 0.1 s for this reaction.15,
19-20
Photocurrent density studies employing
chemical hole scavengers such as sodium sulfite (Na2SO3) have been employed to demonstrate the role of kinetic competition between surface recombination and water oxidation in limiting the performance of BiVO4 photoanodes.7 Herein we report the first direct study of the kinetics of water oxidation on BiVO4 under conditions of photoelectrochemical water oxidation, and employ a rate law analysis of these data to provide insight into the mechanism of water oxidation on this oxide. Compared to the binary metal oxides such as TiO2 and Fe2O3 typically employed as photoanodes for water oxidation, it has been suggested that BiVO4 is unusual in that its valence band edge (VBE) results from the hybridization of Bi(6s) and O(2p) orbitals.21-22 It has also been reported that the photoelectrochemical reactivity of BiVO4 can be strongly modulated by the exposed crystal facet.23 We have recently reported a rate law analysis of the kinetics of water oxidation on hematite photoanodes as a function of the density of surface accumulated valence band holes. This study showed a transition from 1st order behavior at low light flux to 3rd order at higher light fluxes. These data suggested the rather surprising conclusion that, under conditions
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of solar irradiation, the rate determining step for water oxidation on hematite is associated with three valence band holes. This contrasts with the four hole overall stoichiometry required to oxidize two molecules of water to one molecule of oxygen. However it is unclear from this study if this third order behavior is specific to the particular chemistry of water oxidation on hematite (which has been proposed to be associated with the formation of surface iron-oxo groups24), or is more generally observed on other metal oxide surfaces.25-26 Herein, we report the kinetics of water oxidation on undoped, dense BiVO4 photoanodes under quasi steady-state conditions, as determined by spectroelectrochemical photoinduced absorption (PIA) measurements employing pulsed LED excitation. The reaction kinetics were obtained using the rate law analysis employed previously for hematite photoanodes.11 These data are compared against those obtained using potassium ferrocyanide (K4[Fe(CN)6]) as a facile hole scavenger.27-28 The results and implications of the reaction kinetics are discussed with regards to optimization of water oxidation on BiVO4 photoanodes. BiVO4 photoanodes were fabricated using metal-organic deposition,12 yielding dense films with a relatively flat surface (roughness factor ~ 1). Experimental details are given in Supporting Information. Figure 1 shows the typical current-voltage responses of these BiVO4 photoanodes measured in potassium phosphate buffer (KPi, 0.1 M, pH 6.7) with, and without, the addition of K4[Fe(CN)6] (0.2 M) as a hole scavenger. In the KPi buffer, the onset potentials for dark- and photo- water oxidation currents occur at >2.0 VRHE and ~0.8 VRHE, respectively. These results are consistent with previous reports of such BiVO4 photoanodes.12,
16
In contrast, K4[Fe(CN)6]
oxidation dark current onset is 1.0 VRHE, approximately 1 V cathodic of the dark onset in KPi. Under 365 nm LED irradiation, the onset potential for K4[Fe(CN)6] oxidation is 0.55 VRHE, ~250
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mV cathodic of the water oxidation onset potential. Such cathodic shift of current onset is
-2
consistent with previous reports of BiVO4 in the presence of hole scavengers.5, 7, 9
current density / mA cm
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1.5
KPi buffer dark KPi buffer light K4[Fe(CN)6]+KPi buffer dark K4[Fe(CN)6]+KPi buffer light
1.0
0.5
0.0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2
potential vs RHE / V
Figure 1. Current-voltage response of BiVO4 measured in 0.1 M KPi buffer with (red) and without (black) 0.2 M K4[Fe(CN)6] hole scavenger. The dark currents are shown in dashed lines. Scan rate: 10 mV s-1. Light intensity: 365 nm illumination equivalent to 100% AM1.5. In order to investigate the kinetics of water oxidation by photogenerated holes in BiVO4 under quasi steady-state conditions, we carried out spectroelectrochemical PIA measurements in 0.1 M KPi buffer monitoring the photoinduced absorption changes (∆OD) and photocurrent densities (J) induced by pulsed (5 s) 365 nm LED excitation. Data were collected as a function of LED excitation intensity at a fixed applied potential at 1.7 VRHE to ensure effective suppression of surface electron/hole recombination.12,
16
Under these conditions BiVO4 holes exhibit a
maximum absorption change at 550 nm (Figure S2), in agreement with our previous studies of analogous films under pulsed laser excitation.12, 29 As we have previously reported, these quasisteady conditions result in the observation of long-lived holes accumulated at the photoelectrode surface, and thus, measuring the absorption change at 550 nm provides an assay of their reaction
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kinetics. Bulk BiVO4 holes are not monitored in these experiments due to their relatively short (< ns) lifetime.30 The photoinduced absorbance (milli-∆OD, m∆OD) and photocurrent (J) transients results from 5 s pulsed LED excitation are shown in Figures 2 a and b. All ∆OD signals increased from zero to an approximate plateau over a 1 s period from light-on, assigned to surface hole accumulation at the BiVO4/electrolyte interface. In contrast, the transient photocurrent rises within the time resolution of the measurement (0.4 ms), then rapidly decays within a few hundred milliseconds after LED turn on before also plateauing. The initial photocurrent decay most probably derives from a decrease in band bending due to hole accumulation, reducing the photoanode charge separation efficiency, as discussed previously.11 When the excitation light is switched off, the ∆OD signal decays to zero on the seconds timescale, with the slow timescale of this decay being assigned primarily to slow water oxidation by these surface holes, as discussed further below. In contrast, the current decreases to zero rapidly with no negative current transients, indicative of negligible losses from surface back electron/hole recombination under the strongly anodic bias conditions employed. The plateaued photocurrent density, measured between 1 s and 5 s after light-on, was observed to increase linearly with LED intensity, whereas the ∆OD signal increased sub-linearly (Supporting Information Figure S3). This is qualitatively similar to results from Si-doped αFe2O3, reported previously.11 Figure 2c shows the photocurrent density vs ∆OD measured in 0.1 M KPi buffer (red dots) on a log-log scale. Previously we have determined the molar extinction coefficient of photogenerated holes in BiVO4 photoanodes (420 M-1 cm-1),29 allowing us to convert the ∆OD signal amplitude into a surface hole density (ps : holes nm-2) for this plot. From Figure 2c, it is
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apparent that this plot of J versus ps exhibits two distinct phases: a lower gradient for ps < 1 hole nm-2, and a significantly larger gradient at higher surface hole densities. This indicates that the kinetics of water oxidation on BiVO4 are intensity-dependent, showing qualitatively different dependencies on surface hole density at low and high densities. Analogous data to those shown in Figures 2a and 2b were collected in the presence of the hole scavenger K4[Fe(CN)6] (see Figure S4). The applied potential was fixed at 0.7 VRHE to eliminate any contribution from water oxidation; under these conditions the photocurrent can be assigned entirely to K4[Fe(CN)6] oxidation. The resulting plot of J versus ps is also shown in Figure 2c. We note that due to the different electrolyte compositions, and likely changes in surface charge, flat-band potential etc, the absolute magnitudes of the J versus ps cannot be compared with/without K4[Fe(CN)6]. In any case, it is apparent from Figure 2c that the data with K4[Fe(CN)6] shows only one linear region across the light intensity employed, as discussed further below.
0.5
photoinduced absorbance / m∆OD
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87.0 % 37.5 % 6.76 % 0.80 %
(a)
0.4 0.3 0.2 0.1 0.0 0
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4
6
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time / s
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-2
(b)
1.0
0.5
0.0 -2
0
2
4
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8
10
time / s
photoinduced absorbance / m∆OD 100
0.01
0.1
1 1E-3
K4[Fe(CN)6] oxidation
-2
10
-2
α=0.90±0.15
1E-4
-1
water oxidation α=2.92±0.09 α=1.05±0.11
1
1E-5
(c) 0.1
1E-6
0.01
1E-7
0.01
0.1
1
current density / A cm
1E-3
hole flux / s nm
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10 -2
surface hole density / nm
Figure 2. Photo-induced absorption (a) and transient photocurrent density (b) from a BiVO4 photoanode in 0.1 M KPi buffer as a function of light intensity compared to one sun condition. (c) Relationship of PIA amplitude and quasi steady-state photocurrent density for water oxidation (red dots) and K4[Fe(CN)6] oxidation (black squares). We employ a simple kinetic model to interpret these spectroelectrochemical results, as previously used for Si-doped α-Fe2O3,11 and shown as a schematic representation in Scheme 1. We assume the Faraday efficiency is unity on the dense BiVO4 photoanodes employed in these studies.31 No impurities, such as trace of Fe or Ni on the electrode surface from the electrolyte, were deposited as catalysts,32-35 according to our previous X-ray photoelectron spectroscopy
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result.29 Therefore, the results shown herein represent water oxidation by photogenerated holes in BiVO4. Under 1.7 VRHE anodic potential, we considered a model for surface-accumulated holes at the semiconductor-electrolyte interface as follows: (1)
dps α = J hole − k × ps dt
where ps is the hole density at the BiVO4 surface, Jhole is the hole flux to the surface during irradiation, k is the rate constant of reaction of holes with water/potassium ferrocyanide and α is the reaction order in suface hole density. At steady state (i.e.: after 5 s irradiation), the rate of change in surface hole density is zero, therefore Equation 1 can be written as: (2)
dps α = J hole − k × ps = 0 dt α
(3) J hole = k × ps ; J photo = J hole (4) log( J photo ) = log k + α × log p s where Jphoto is the steady-state photocurrent density measured at 5 s after light-on (Figure 2b). Jphoto
O2/H2O
-
FTO
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Water oxidation kWO × psα + +
Jhole
Surface holes, ps
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Scheme 1. Schematic representation of surface accumulated holes in the BiVO4 photoanodes oxidizing water. The dashed horizontal line is the dark Fermi level of the photoanode determined by the applied potential. Following equation 4, the photocurrent density J should, on a log-log scale, increase linearly with increasing surface hole density ps, with the gradient corresponding to the reaction order α. Figure 2c shows the rate of oxidation of K4[Fe(CN)6] increases linearly with hole density, corresponding to first order kinetics (α=0.90±0.15 and k=0.8 s-1) in surface hole density over the light intensity range employed in this study (0.8 to 81 % of AM 1.5). The first order reaction determined from our rate law analysis indicates that the oxidation of K4[Fe(CN)6] involves a single electron redox process, consistent with the redox reaction of [Fe(CN)6]3-/[Fe(CN)6]4shown below. [ Fe (CN ) 6 ] 4 − + h + → [ Fe (CN ) 6 ]3−
Under irradiation, one [Fe(CN)6]4- complex receives one photogenerated hole from BiVO4, forming one [Fe(CN)6]3-. The redox potential of [Fe(CN)6]3-/[Fe(CN)6]4- is 0.36 VRHE. Therefore, the BiVO4 valence band edge (2.6 VRHE) can provide significantly more driving force for the oxidation of [Fe(CN)6]4- than for single-hole water oxidation (2.8 VRHE).36 Thus, the thermodynamic driving force is more favorable for BiVO4 surface holes to oxidize K4[Fe(CN)6] than water. In contrast to the first order reaction of K4[Fe(CN)6] oxidation as a function of surface hole density, Figure 2c also shows that there are two regimes of linearity for water oxidation. Under low surface hole density (ps < 1 hole nm-2), water oxidation proceeds with first-order (in holes) reaction kinetics (α=1.05±0.11); at surface hole densities higher than 1 nm-2, the reaction order of water oxidation (in holes) becomes third order (α=2.92±0.09). In order to provide further
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support for this change in reaction order, different rate law analyses were carried out: differentiation of the gradient of one complete PIA decay after light-off; an initial slopes analysis of several PIA decays under different excitation intensities (details are shown in Supporting Information Figure S5); and kinetic analysis of transient absorption spectroscopic (TAS) data previously recorded, showing a mono-exponential decay of surface hole as a function of time for water oxidation.12 The results of these analyses are shown in Figure 3. It is apparent that these different analyses are in excellent agreement with each other – indicating a change in reaction order from 1st to third order at ps ~ 1 hole nm-2.
3
reaction order
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2
decay slope PIA vs Jphoto
1
TAS initial slope
0 0
1
2
3
4
5
-2
surface hole density / nm
Figure 3. Change in reaction order as a function of surface hole density, determined from four independent methods of analysis. Red line: a guide for the eye (not fit to a model). The rate constants for both the first and third order water oxidation on BiVO4 reactions can be calculated from the fit of Figure 2c using Equation 4. For the first order of water oxidation in holes, the rate constant is 0.5 s-1; for the third order reaction, the rate constant is 0.8 s-1 hole-2 nm4. These rate constants are both faster than the corresponding rate constants determined for hematite, 0.2 s-1 and 0.5 s-1 hole-2 nm4, respectively,11 particularly for the 3rd order reaction. The faster rate constants observed on BiVO4 could be associated with the deeper valence band edge
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for BiVO4 (2.6 eV) compared to Si-doped α-Fe2O3 (2.4 eV) providing a large energy offset driving water oxidation, although we note that other factors may also be important (e.g.: electrolyte pH, valence band structure, surface facet etc). The transition of BiVO4’s water oxidation kinetics from first to third in surface hole density (ps) as ps is increased is strikingly similar to the behavior we have reported previously for Fe2O3.11 The first order behavior at low surface hole densities indicates that the rate-limiting step in water oxidation only involves one surface hole; •OH formation has been suggested as the key intermediate for the single hole oxidation of water, likely to lead to both H2O2 and O2 formation.36 The third order reaction kinetics under high surface hole densities is consistent with, for example, a mechanism involving the formation of an O-O bridging bond between two reaction sites, which consumes three surface accumulated holes. Such mechanisms have been suggested for water oxidation on some metal oxide materials, including Co3O425 and α-Fe2O311, 24
, from either detecting the time-resolved IR response during the formation of rate-limiting
intermediates on Co3O4, or employing a rate law analysis to determine the reaction order. We are aware that studies of the mechanism of water oxidation are still limited due to the difficulties in probing the intermediates involved. However, our observation of remarkably similar 1st/3rd behavior on BiVO4 to that we have observed for Fe2O3 is striking as these oxides present predominantly different surface facets ((121) for the BiVO4 studied herein versus (110) for the Si-doped Fe2O3 reported previously11, 37) and difference valence band hole natures (hybridized O(2p) and Bi(6s) for BiVO4 and hybridized Fe(3d) and O(2p) for α-Fe2O3). It suggests the mechanisms of water oxidation on these two oxides may exhibit close similarities, which has important implications for the development of mechanistic models of water oxidation on this oxide photoanodes.
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The slow kinetics of water oxidation on metal oxide surfaces is a key challenge for photoelectrochemical water oxidation on such materials. Such slow kinetics have been reported by a various spectroscopic techniques, including transient absorption spectroscopy,12-13, 17-18, 38-40 impedance spectroscopy41 and intensity-modulated photocurrent spectroscopy.15, 19-20 Such slow kinetics result in a requirement for the accumulation of large hole densities at the photoanode surface to drive the required water oxidation current densities, with a resulting increase in surface recombination losses.12, 14, 17 The super-linear increase in the rate of water oxidation as the surface hole density is increased is likely to be a key factor behind the efficient photoelectrochemical water oxidation reported to date for several metal oxide photoanodes. For the BiVO4 studied herein, the effective turn over frequency (TOF) of each surface hole increases from 0.3 s-1 at 0.1 hole nm-2 to 14 s-1 at 5 holes nm-2 (corresponding to ~ one sun irradiation conditions). The faster TOF’s for BiVO4 compared to hematite (5 s-1 at 5 holes nm-2)11 may result from its deeper valence band energetics, or from other factors such as lateral surface hole mobilities. In any case, the faster TOF is likely to be one factor behind the less anodic applied biases required to drive efficient water oxidation on BiVO4 compared to hematite photoanodes. We note that the water oxidation kinetics we report herein on BiVO4 are faster in terms of TOF per surface hole/catalytic site compared to those reported for widely used water oxidation electrocatalysts. For example, TOF’s for the cobalt phosphate (CoPi) electrocatalyst have been reported to be in the range 0.01-0.001 s-1.42 The faster kinetics on BiVO4 can be attributed to its deep valence band energy providing a large overpotential for water oxidation (with this large overpotential of course being undesirable in terms of energy conversion efficiency). As such, several studies have indicated that following CoPi deposition on BiVO4, water oxidation primarily proceeds directly from BiVO4 holes rather than via CoPi oxidation, with enhanced
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performance in the presence of CoPi being primarily assigned to reduced recombination losses due enhanced space charge layer formation induced by the BiVO4/CoPi junction, similar to studies of α-Fe2O3/CoPi junctions.19,
43-45
We have reported previously PIA and transient
absorption spectroscopies of CoPi-modified BiVO4 photoanodes and have observed that CoPi overlayers did not contribute to significant PEC water oxidation under both pulsed laser and continuous wave LED conditions for the electrodes employed in these studies.16,
29
Surface
functionalization by co-catalysts is a widely used strategy to enhance the performance of water oxidation photoanodes. Our observation herein of TOF as high as 14 s-1 per surface hole on BiVO4 provides a clear kinetic challenge for this approach, i.e. that water oxidation by the cocatalyst should be faster than that on BiVO4 alone, and emphasizes that such strategies must consider both the kinetics of water oxidation on both semiconductor and co-catalyst surfaces as well as the impact of co-catalyst deposition upon recombination losses in the photoelectrode.
ASSOCIATED CONTENT Supporting Information. Material preparation, description of photoelectrochemistry and spectroelectrochemistry, PIA spectrum of BiVO4 photogenerated holes, steady-state PIA amplitude and photocurrent as a function of light intensity, PIA and transient photocurrent signals of photogenerated holes in a BiVO4 photoanode for ferrocyanide oxidation measured under 5 s LED irradiation, rate law analyses.
AUTHOR INFORMATION
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Ernest Pastor current address: Physical Biosciences Division, Lawrence Berkeley National Laboratory, Berkeley, California 94720, United States Notes The authors declare no competing financial interests. ACKNOWLEDGMENT The authors thank the European Research Council (project Intersolar 291482) for funding. C. M. thanks COLCIENCIAS for funding. E.P. thanks EPSRC for award of a DTP studentship. A.K. thanks the Ramsay Memorial Fellowships Trust. F.L.F. thanks the Swiss National Science Foundation (project: 140709). L.F.F. thanks the CEC for the award of a Marie Curie Fellowship. . REFERENCES (1) Park, Y.; McDonald, K. J.; Choi, K.-S. Progress in bismuth vanadate photoanodes for use in solar water oxidation. Chem. Soc. Rev. 2013, 42, 2321-2337. (2) Gratzel, M. Photoelectrochemical cells. Nature 2001, 414, 338-344. (3) Kudo, A.; Miseki, Y. Heterogeneous photocatalyst materials for water splitting. Chem. Soc. Rev. 2009, 38, 253-278. (4) Abdi, F. F.; Han, L.; Smets, A. H. M.; Zeman, M.; Dam, B.; van de Krol, R. Efficient solar water splitting by enhanced charge separation in a bismuth vanadate-silicon tandem photoelectrode. Nat. Commun. 2013, 4, 2195. (5) Abdi, F. F.; Firet, N.; van de Krol, R. Efficient BiVO4 Thin Film Photoanodes Modified with Cobalt Phosphate Catalyst and W-doping. ChemCatChem 2013, 5, 490-496. (6) Abdi, F. F.; van de Krol, R. Nature and Light Dependence of Bulk Recombination in CoPi-Catalyzed BiVO4 Photoanodes. J. Phys. Chem. C 2012, 116, 9398-9404. (7) Kim, T. W.; Choi, K. S. Nanoporous BiVO4 photoanodes with dual-layer oxygen evolution catalysts for solar water splitting. Science 2014, 343, 990-994. (8) Seabold, J. A.; Choi, K.-S. Efficient and Stable Photo-Oxidation of Water by a Bismuth Vanadate Photoanode Coupled with an Iron Oxyhydroxide Oxygen Evolution Catalyst. J. Am. Chem. Soc. 2012, 134, 2186-2192. (9) Zhong, D. K.; Choi, S.; Gamelin, D. R. Near-complete suppression of surface recombination in solar photoelectrolysis by "Co-Pi" catalyst-modified W:BiVO4. J. Am. Chem. Soc. 2011, 133, 18370-18377.
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